Ladder-type elastic wave filter and antenna duplexer using same

ABSTRACT

In a ladder-type elastic wave filter, a resonance frequency of a second parallel resonator is higher than that of a series resonator and lower than an antiresonance frequency of a series resonator. With this configuration, an attenuation pole is formed by the second parallel resonator at a frequency region lower than an attenuation pole formed by the series resonator in a frequency region higher than the passband of the ladder-type elastic wave filter.

BACKGROUND

1. Technical Field

The present technical field relates to a ladder-type elastic wave filterand an antenna duplexer using the same.

2. Background Art

A conventional ladder-type elastic wave filter is described withreference to a drawing. FIG. 13 is a circuit block diagram of aconventional antenna duplexer which includes a ladder-type elastic wavefilter.

In FIG. 13, conventional antenna duplexer 101 is, for example, anantenna duplexer of the UMTS system, and includes ladder-type elasticwave filter 102 as a transmission filter and reception filter 103 havinga passband higher than a passband of ladder-type elastic wave filter102. Ladder-type elastic wave filter 102 is connected between inputterminal 104 and antenna terminal 105, receives a transmission signalfrom input terminal 104, and outputs it from antenna terminal 105.Ladder-type elastic wave filter 102 includes series resonators 108, 109,110, and 111, and parallel resonators 112, 113, and 114 having a lowerresonance frequency than antiresonance frequencies of the seriesresonators, which are connected to each other in a ladder form.Furthermore, ground terminal 117 sides of parallel resonators 112, 113,and 114 are connected to each other at connection part 116, andladder-type elastic wave filter 102 includes inductor 115 connectedbetween connection part 116 and ground terminal 117.

Furthermore, reception filter 103 includes, for example, resonator 119and longitudinal mode coupled filter 118, which are connected betweenantenna terminal 105 and output terminal (balanced terminal) 106.Reception filter 103 receives a received signal from antenna terminal105 and outputs it from output terminal 106.

Furthermore, antenna duplexer 101 includes phase shifter 107 connectedbetween ladder-type elastic wave filter 102 and reception filter 103.Phase shifter 107 allows the passband of each of the transmission andreception filters to have a higher impedance in view of each other so asto improve isolation to each other.

SUMMARY

The present disclosure provides a ladder-type elastic wave filter inwhich steepness of passing characteristic at a frequency region higherthan a passband thereof is secured. The ladder-type elastic wave filteraccording to various embodiments includes a series resonator connectedbetween an input terminal and an output terminal; a first parallelresonator connected between the series resonator and a ground terminal,and having a resonance frequency lower than an antiresonance frequencyof the series resonator; and a second parallel resonator connected inparallel to the first parallel resonator. The second parallel resonatorhas a resonance frequency higher than the resonance frequency of theseries resonator and lower than the antiresonance frequency of theseries resonator.

With the above-mentioned configuration, at the frequency region higherthan the passband of the ladder-type elastic wave filter, an attenuationpole by the second parallel resonator is formed in a lower frequencyregion than an attenuation pole formed by the series resonator. Thismakes it possible to secure steepness of the passing characteristic atthe frequency region higher than the passband of the ladder-type elasticwave filter.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a circuit block diagram of an antenna duplexer including aladder-type elastic wave filter in accordance with a first exemplaryembodiment of the present disclosure.

FIG. 2 is a sectional schematic view of the ladder-type elastic wavefilter in accordance with the first exemplary embodiment of the presentdisclosure.

FIG. 3 is a sectional schematic view of the ladder-type elastic wavefilter in accordance with the first exemplary embodiment of the presentdisclosure.

FIG. 4 is a characteristic comparison graph between the ladder-typeelastic wave filter in accordance with the first exemplary embodiment ofthe present disclosure and a conventional ladder-type elastic wavefilter.

FIG. 5 is a circuit block diagram of an antenna duplexer including aladder-type elastic wave filter in accordance with the first exemplaryembodiment of the present disclosure.

FIG. 6 is an upper schematic view of a second parallel resonator of theladder-type elastic wave filter in accordance with the first exemplaryembodiment of the present disclosure.

FIG. 7 is a circuit block diagram of an antenna duplexer including aladder-type elastic wave filter in accordance with a second exemplaryembodiment of the present disclosure.

FIG. 8 is a characteristic comparison graph between the ladder-typeelastic wave filter in accordance with the second exemplary embodimentof the present disclosure and a conventional ladder-type elastic wavefilter.

FIG. 9A is a characteristic graph of a conventional ladder-type elasticwave filter.

FIG. 9B is a characteristic comparison graph between the ladder-typeelastic wave filter in accordance with the second exemplary embodimentof the present disclosure and a conventional ladder-type elastic wavefilter.

FIG. 9C is a characteristic comparison graph between the ladder-typeelastic wave filter in accordance with the second exemplary embodimentof the present disclosure and a conventional ladder-type elastic wavefilter.

FIG. 9D is a characteristic comparison graph between the ladder-typeelastic wave filter in accordance with the second exemplary embodimentof the present disclosure and a conventional ladder-type elastic wavefilter.

FIG. 9E is a characteristic comparison graph between the ladder-typeelastic wave filter in accordance with the second exemplary embodimentof the present disclosure and a conventional ladder-type elastic wavefilter.

FIG. 9F is a characteristic comparison graph between the ladder-typeelastic wave filter in accordance with the second exemplary embodimentof the present disclosure and a conventional ladder-type elastic wavefilter.

FIG. 9G is a characteristic comparison graph between the ladder-typeelastic wave filter in accordance with the second exemplary embodimentof the present disclosure and a conventional ladder-type elastic wavefilter.

FIG. 9H is a characteristic comparison graph between the ladder-typeelastic wave filter in accordance with the second exemplary embodimentof the present disclosure and a conventional ladder-type elastic wavefilter.

FIG. 9I is a characteristic comparison graph between the ladder-typeelastic wave filter in accordance with the second exemplary embodimentof the present disclosure and a conventional ladder-type elastic wavefilter.

FIG. 9J is a characteristic comparison graph between the ladder-typeelastic wave filter in accordance with the second exemplary embodimentof the present disclosure and a conventional ladder-type elastic wavefilter.

FIG. 9K is a characteristic comparison graph between the ladder-typeelastic wave filter in accordance with the second exemplary embodimentof the present disclosure and a conventional ladder-type elastic wavefilter.

FIG. 10 is a circuit block diagram of an antenna duplexer including aladder-type elastic wave filter in accordance with the second exemplaryembodiment of the present disclosure.

FIG. 11 is an upper schematic view of a second parallel resonator of theladder-type elastic wave filter in accordance with the second exemplaryembodiment of the present disclosure.

FIG. 12 is a circuit block diagram of an antenna duplexer including aladder-type elastic wave filter in accordance with a third exemplaryembodiment of the present disclosure.

FIG. 13 is a circuit block diagram of an antenna duplexer including aconventional ladder-type elastic wave filter.

DETAILED DESCRIPTION OF PREFERRED EMBODIMENTS

Prior to description of exemplary embodiments, problems of aconventional configuration are described. In ladder-type elastic wavefilter 102 that is a transmission filter of conventional antennaduplexer 101, antiresonance frequencies of series resonators 108, 109,110, and 111 are set in the vicinity of a frequency region higher thanthe passband of ladder-type elastic wave filter 102, and resonancefrequencies of parallel resonators 112, 113, and 114 are set in thevicinity of a frequency region lower than ladder-type elastic wavefilter 102. Thereby, attenuation poles are formed in the vicinity ofboth higher and lower frequency region than the passband of ladder-typeelastic wave filter 102. However, it is difficult to secure steepness ofpassing characteristic at the frequency region higher than the passbandof ladder-type elastic wave filter 102 as a transmission filter ofconventional antenna duplexer 101.

First Exemplary Embodiment

Hereinafter, an elastic wave element in accordance with a firstexemplary embodiment of the present disclosure is described withreference to drawings. FIG. 1 is a circuit block diagram of antennaduplexer 1 including a ladder-type elastic wave filter in accordancewith the first exemplary embodiment.

In FIG. 1, antenna duplexer 1 including the ladder-type elastic wavefilter in accordance with the first exemplary embodiment is, forexample, an antenna duplexer for Band-8 of the UMTS system, and includesladder-type elastic wave filter 2 as a transmission filter and receptionfilter 3 having a passband (925 MHz to 960 MHz) higher than a passband(880 MHz to 915 MHz) of ladder-type elastic wave filter 2. Furthermore,antenna duplexer 1 includes phase shifter 7 connected betweenladder-type elastic wave filter 2 and reception filter 3. Phase shifter7 allows the passband of each of the transmission and reception filtersto have a higher impedance in view of each other so as to improveisolation between the transmission and reception filters.

Reception filter 3 includes, for example, resonator 19 and longitudinalmode coupled filter 18 which are connected between antenna terminal 5and output terminal (balanced terminal) 6, and receives a receivedsignal from antenna terminal 5 and outputs it from output terminal 6.

Ladder-type elastic wave filter 2 as the transmission filter isconnected between input terminal 4 and antenna terminal 5 (an outputterminal of ladder-type elastic wave filter 2), receives a transmissionsignal from input terminal 4 and outputs it from antenna terminal 5.Ladder-type elastic wave filter 2 includes series resonators 8, 9, 10,and 11 each of which is connected to each of a plurality of series arms,and first parallel resonators 12, 13, and 14 each of which is connectedto each of a plurality of parallel arms, in which series resonators 8,9, 10, and 11 and first parallel resonators 12, 13, and 14 are connectedto each other in a ladder form. Resonance frequencies of first parallelresonators 12, 13, and 14 are lower than resonance frequencies orantiresonance frequencies of series resonators 8, 9, 10, and 11.

Furthermore, ground terminal 17 sides of first parallel resonators 12,13, and 14 are connected to each other at connection part 16,ladder-type elastic wave filter 2 includes inductor 15 connected betweenconnection part 16 and ground terminal 17.

In ladder-type elastic wave filter 2 thus constructed as thetransmission filter in antenna duplexer 1, the antiresonance frequenciesof series resonators 8, 9, 10, and 11 are set in the vicinity of thepassband of ladder-type elastic wave filter 2 in a frequency regionhigher than the passband of ladder-type elastic wave filter 2, and theresonance frequencies of first parallel resonators 12, 13, and 14 areset in the vicinity of the passband of ladder-type elastic wave filter 2in a frequency region lower than the passband of ladder-type elasticwave filter 2. Attenuation poles are formed in the both vicinities ofthe passband of ladder-type elastic wave filter 2 at the higher andlower frequency sides.

In addition, in antenna duplexer 1, ladder-type elastic wave filter 2includes second parallel resonator 20 connected in parallel to firstparallel resonator 12 by one of the parallel arms and having a resonancefrequency higher than resonance frequencies of resonators 8, 9, 10, and11 and lower than antiresonance frequencies of series resonators 8, 9,10, and 11. Second parallel resonator 20 operates as a band attenuationfilter (notch filter) that attenuates an input signal around theresonance frequency of second parallel resonator 20. Note here thatsecond parallel resonator 20 may be singly connected to a parallel armbetween one of the series resonators and the ground terminal withoutbeing connected to any of the parallel arms to which the first parallelresonators are connected respectively.

With the above-mentioned configuration, in ladder-type elastic wavefilter 2, an attenuation pole by the second parallel resonator is formedin a frequency region lower than an attenuation pole formed by theseries resonators in a frequency region higher than the passband ofladder-type elastic wave filter 2. Thus, it is possible to securesteepness of the passing characteristics in a frequency region higherthan the passband of ladder-type elastic wave filter 2.

Each component of ladder-type elastic wave filter 2 of the firstexemplary embodiment is described in detail with reference to FIGS. 1and 2. FIG. 2 is a sectional schematic view of ladder-type elastic wavefilter 2 of the first exemplary embodiment.

In ladder-type elastic wave filter 2, series resonators 8, 9, 10, and11, first parallel resonators 12, 13, and 14, and second parallelresonator 20 are formed on piezoelectric substrate 30. Furthermore,inductor 15 may be formed on piezoelectric substrate 30 directly orindirectly via a dielectric layer, or may be formed on a laminatedceramic substrate (not shown) on which piezoelectric substrate 30 ismounted.

Piezoelectric substrate 30 is, for example, a quartz, lithium niobate(LiNbO₃)-based, or lithium tantalate (LiTaO₃)-based, potassium niobate(KNbO₃)-based piezoelectric monocrystal substrate. When dielectric layer31 is formed on piezoelectric substrate 30 so as to cover resonators 8to 14, and 20, dielectric layer 31 is formed of, for example, siliconoxide (SiO₂), silicon nitride (SiN), aluminum nitride (AlN), or alaminated body thereof. Even when dielectric layer 31 may be formed inthe same thickness on resonators 8 to 14, and 20, it is possible toobtain the effect of the steepness of ladder-type elastic wave filter 2,which is the effect of the disclosure. Note here that when dielectriclayer 31 has a frequency temperature coefficient with an opposite signto a frequency temperature coefficient of piezoelectric substrate 30such as silicon oxide (SiO₂), it is desirable that film thickness Ha ofdielectric layer 31 on a comb electrode of second parallel resonator 20is larger than film thickness Hb of dielectric layer 31 on a combelectrode of first parallel resonators 12, 13, and 14. Furthermore, asshown in FIG. 3, when dielectric layer 31 is provided on the combelectrode of second parallel resonator 20, dielectric layer 31 may notbe provided on first parallel resonators 12, 13, and 14. Such aconfiguration can improve frequency temperature characteristics ofsecond parallel resonator 20 which have the most effect on the filterproperty, among resonators 12, 13, 14, and 20 forming a filter propertyin a frequency region higher than the passband of ladder-type elasticwave filter 2. That is to say, in antenna duplexer 1, it is possible toobtain the passing characteristics of antenna duplexer 1 in a cross-bandbetween the passband of ladder-type elastic wave filter 2 as thetransmission filter and the passband of reception filter 3.

Each of series resonators 8, 9, 10, and 11, first parallel resonators12, 13, and 14, and second parallel resonator 20 includes a pair of combelectrodes (interdigital transducer electrodes) and two reflectorssandwiching the comb electrodes in the propagation direction of mainelastic wave. The comb electrodes and the reflectors are formed on apiezoelectric substrate. The comb electrodes constituting theseresonators are formed of, for example, simple substance of metalincluding aluminum, copper, silver, gold, titanium, tungsten,molybdenum, platinum, or chromium, or alloys including the metal as amain component, or a laminated body thereof. Note here that the combelectrode may be an electrode that excites a surface acoustic wave suchas SH (Shear Horizontal) wave, Reilly, or the like, as primary wave, ormay be an electrode that excites a bulk wave such as a Lamb wave.

The resonance frequency [GHz] and the antiresonance frequency [GHz] ofeach of series resonators 8, 9, 10, and 11, and second parallelresonator 20 are shown in Table 1.

TABLE 1 resonance antiresonance frequency (GHz) frequency (GHz) seriesresonator 8 0.89 0.925 series resonator 9 0.90 0.93 series resonator 100.91 0.94 series resonator 11 0.90 0.93 second parallel resonator 200.92 0.95

The resonance frequency [GHz] and the antiresonance frequency [GHz] ofeach of series resonators 108, 109, 110, and 111 in conventionalladder-type elastic wave filter 102 of FIG. 13 are shown in Table 2.

TABLE 2 resonance frequency antiresonance (GHz) frequency (GHz) seriesresonator 108 0.89 0.92 series resonator 109 0.90 0.93 series resonator110 0.91 0.94 series resonator 111 0.90 0.93

Characteristic comparison between ladder-type elastic wave filter 2 ofthe first exemplary embodiment and conventional ladder-type elastic wavefilter 102 is shown in FIG. 4. A characteristic shown by a solid line inFIG. 4 is a characteristic of ladder-type elastic wave filter 2 of thefirst exemplary embodiment and a characteristic shown by a broken lineis a characteristic of conventional ladder-type elastic wave filter 102.In FIG. 4, the abscissa shows a frequency [MHz], and the ordinate showsgain [dB]. Note here that downward triangles show an upper limit and alower limit of the frequency in the passband of the filters,respectively.

As shown in FIG. 4, it is shown that ladder-type elastic wave filter 2is improved in the steepness of the passing characteristics in afrequency region higher than the passband of ladder-type elastic wavefilter 2 as compared with that of the conventional ladder-type elasticwave filter 102.

Note here that series resonator 108 having the lowest antiresonancefrequency has larger power consumption as compared with that of theother series resonators 109, 110, and 111, and it easily generates heat.Thus, when the resonance frequency of second parallel resonator 20 isset to be lower than the antiresonance frequency of series resonator 8having the lowest antiresonance frequency among series resonators 8, 9,10, and 11 in ladder-type elastic wave filter 2 of the first exemplaryembodiment, the antiresonance frequency of series resonator 8 can beshifted to a higher frequency region side from the antiresonancefrequency of conventional series resonator 108, and heat generation ofseries resonator 8 can be suppressed. In this case, in second parallelresonator 20, since excitation of primary elastic wave in the frequencyregion lower than the resonance frequency is suppressed, heat generationis suppressed. As a result, electric power resistance of ladder-typeelastic wave filter 2 can be improved.

Furthermore, it is desirable that second parallel resonator 20 hascapacitance smaller than that of first parallel resonators 12, 13, and14. The reason for this is described below. In a frequency region lowerthan the attenuation pole formed by second parallel resonator 20, secondparallel resonator 20 as a band attenuation filter shows capacitativeproperty. Thus, when capacitance of second parallel resonator 20 islarger than capacitance of first parallel resonators 12, 13, and 14,steepness in the frequency region higher than the passband ofladder-type elastic wave filter 2 is deteriorated in the frequencyregion lower than the attenuation pole formed by second parallelresonator 20. Then, when the capacitance of second parallel resonator 20is made to be smaller than the capacitance of first parallel resonators12, 13, and 14, the steepness at the frequency region higher than thepassband of ladder-type elastic wave filter 2 can be improved.

Furthermore, although not shown in the drawings, it is desirable thatsecond parallel resonator 20 is connected in parallel to first parallelresonator 13 by the same parallel arm. First parallel resonator 13 isother than first parallel resonator 12 that is nearest to input terminal4 among a plurality of first parallel resonators. An electrode fingerpitch of second parallel resonator 20 is smaller than electrode fingerpitches of series resonators 8, 9, 10, and 11, and first parallelresonators 12, 13, and 14, and electric power resistance of secondparallel resonator 20 is relatively low. Thus, when second parallelresonator 20 is not connected to the parallel arm at an input terminal 4side that requires the largest electric power resistance but connectedto a parallel arm other than the parallel arm, the electric powerresistance of ladder-type elastic wave filter 2 can be improved.

Furthermore, as shown in FIG. 5, it is desirable that second parallelresonator 20 has a configuration in which each of a plurality ofresonators 21 and 22 is cascade connected to each other. The electrodefinger pitch of second parallel resonator 20 is smaller than theelectrode finger pitches of first parallel resonators 12, 13, and 14,and the electric power resistance of second parallel resonator 20 isrelatively low. Thus, when second parallel resonator 20 includescascade-connected resonators 21 and 22, electric power resistance ofsecond parallel resonator 20 is improved, and electric power resistanceof ladder-type elastic wave filter 2 can be enhanced. In particular, thecascade connection configuration of resonators 21 and 22 is particularlypreferable because electric power resistance of second parallelresonator 20 can be enhanced when the capacitance of second parallelresonator 20 is not more than that of first parallel resonator 12connected to the same parallel arm as that of second parallel resonator20.

Note here that the capacitance of each of resonators 21 and 22 is twiceas large as the capacitance of second parallel resonator 20 in FIG. 1.As the means, for example, an interdigitating width of electrode fingersof each of resonators 21 and 22 may be twice as that of second parallelresonator 20 in FIG. 1, or the number of electrode fingers may be twiceas many as that of second parallel resonator 20 in FIG. 1. When secondparallel resonator 20 includes a plurality of cascade-connectedresonators, making capacitance of each resonator equal to each otherallows the applied voltage to be divided uniformly among the resonators.As a result, electric power resistance of second parallel resonator 20is further improved, and electric power resistance of ladder-typeelastic wave filter 2 can be further improved.

Furthermore, when the capacitance of second parallel resonator 20 is notmore than the capacitance of first parallel resonator 12, it ispreferable that a total occupied area of resonators 21 and 22constituting second parallel resonator 20 is made to be larger than thatof first parallel resonator 12. Thanks to the constitution, electricpower resistance of second parallel resonator 20 is improved.

Furthermore, second parallel resonator 20 shown in FIG. 5 is divided ina propagation direction of the elastic wave as shown in FIG. 6, and maybe a resonator including a comb electrode having electrode fingers inwhich each of the divided regions 23 and 24 are disposed in an oppositephase to each other, and reflectors 25 and 26 sandwiching thereof. Thedivided regions 23 and 24 form resonators 21 and 22 shown in FIG. 5,respectively. Note here that terminal 27 is connected to seriesresonators 8 and 9, and terminal 28 is connected to connection part 16.With this configuration, while the electric power resistance of secondparallel resonator 20 is secured and the occupied area can be reduced,and the attenuation pole formed by second parallel resonator 20 isincreased, thus the attenuation characteristics in the frequency regionhigher than the passband of ladder-type elastic wave filter 2 areimproved.

Note here that second parallel resonator 20 shown in FIGS. 5 and 6 isdivided into two parts, but it may be divided into three parts or moreso as to further improve electric power resistance of second parallelresonator 20.

Furthermore, the first exemplary embodiment describes second parallelresonator 20 having a resonance frequency higher than the resonancefrequencies of series resonators 8, 9, 10, and 11 and lower than theantiresonance frequencies thereof. However, when greater importance isplaced on the attenuation characteristics than the steepness, secondparallel resonator 20 may have resonance frequency higher than that ofat least one of series resonators 8, 9, 10, and 11 and lower thanantiresonance frequency of at least one of resonators 8, 9, 10, and 11and lower.

Furthermore, in antenna duplexer 1 such as a duplexer including a firstfilter and a second filter having a higher passband of the first filter,it is preferable that ladder-type elastic wave filter 2 is used as thefirst filter having a relatively low passband. Thanks to the structure,it is possible to secure steepness of the passing characteristics of thefirst filter in the cross-band between the passband of the first filterand the passband of the second filter. That is to say, in the case ofthe above-mentioned ladder-type elastic wave filter 2, it is possible tosecure steepness of the passing characteristics of the ladder-typeelastic wave filter 2 in the cross-band between the passband of theladder-type elastic wave filter 2 as a transmission filter and thepassband of reception filter 3. Herein, by setting the resonancefrequency of second parallel resonator 20 of a first filter (ladder-typeelastic wave filter 2 as a transmission filter) in the passband of asecond filter (reception filter 3), attenuation characteristics can befurther improved.

Furthermore, ladder-type elastic wave filter 2 of the first exemplaryembodiment may be mounted on an electronic apparatus provided with asemiconductor integrated circuit element (not shown) connected to thefilter and an audio unit (not shown) such as a loudspeaker connected tothe semiconductor integrated circuit element (not shown). Thus,communication quality of the electronic apparatus can be improved.

Second Exemplary Embodiment

Hereinafter, an elastic wave element in accordance with a secondexemplary embodiment of the present disclosure is described withreference to drawings. FIG. 7 is a circuit block diagram of antennaduplexer 1 on which a ladder-type elastic wave filter in accordance withthe second exemplary embodiment is mounted.

In FIG. 7, antenna duplexer 1 on which the ladder-type elastic wavefilter in accordance with the second exemplary embodiment is mounted is,for example, an antenna duplexer for Band-8 of the UMTS system, andincludes ladder-type elastic wave filter 2 as a transmission filter andreception filter 3 having a passband (925 MHz to 960 MHz) higher than apassband (880 MHz to 915 MHz) of ladder-type elastic wave filter 2.

Furthermore, antenna duplexer 1 includes phase shifter 7 connectedbetween ladder-type elastic wave filter 2 and reception filter 3. Phaseshifter 7 allows the passband of each of the transmission and receptionfilters to have a higher impedance in view of each other so as toimprove isolation between the transmission and reception filters.

Reception filter 3 includes, for example, resonator 19 and longitudinalmode coupled filter 18, which are connected between antenna terminal 5and output terminal (balanced terminal) 6, and receives a receivedsignal from antenna terminal 5 and outputs it from output terminal 6.

Ladder-type elastic wave filter 2 as the transmission filter isconnected between input terminal 4 and antenna terminal 5 (an outputterminal of ladder-type elastic wave filter 2), receives a transmissionsignal from input terminal 4 and outputs it from antenna terminal 5.Ladder-type elastic wave filter 2 includes series resonators 8, 9, 10,and 11 each of which is connected to each of a plurality of series arms,and first parallel resonators 12, 13, and 14 each of which is connectedto each of a plurality of parallel arms, in which series resonators 8,9, 10 and 11 and first parallel resonators 12, 13 and 14 are connectedto each other in a ladder form. Resonance frequencies of first parallelresonators 12, 13, and 14 are lower than resonance frequencies orantiresonance frequencies of series resonators 8, 9, 10, and 11.

Furthermore, ground terminal 17 sides of first parallel resonators 12,13, and 14 are connected to each other at connection part 16,ladder-type elastic wave filter 2 includes inductor 15 connected betweenconnection part 16 and ground terminal 17.

In such a ladder-type elastic wave filter 2 as the transmission filterin antenna duplexer 1, the antiresonance frequencies of seriesresonators 8, 9, 10, and 11 are set in the vicinity of the passband ofladder-type elastic wave filter 2 in a frequency region higher than thepassband of ladder-type elastic wave filter 2, and the resonancefrequencies of first parallel resonators 12, 13, and 14 are set in thevicinity of the passband of ladder-type elastic wave filter 2 in afrequency region lower than the passband of ladder-type elastic wavefilter 2. Attenuation poles are thus formed in the both vicinities ofthe passband of ladder-type elastic wave filter 2 at the higher andlower frequency sides.

In addition, in antenna duplexer 1, ladder-type elastic wave filter 2includes third parallel resonator 40 connected in parallel to firstparallel resonator 13 by one of the parallel arms and having resonancefrequency higher than antiresonance frequencies of resonators 8, 9, 10,and 11. Third parallel resonator 40 operates as a band attenuationfilter (notch filter) that attenuates an input signal around theresonance frequency of third parallel resonator 40. Note here that thirdparallel resonator 40 may be singly connected to a parallel arm betweenone of the series resonators and the ground terminal without beingconnected to any of the parallel arms to which the first parallelresonators are connected, respectively.

With the above-mentioned configuration, in ladder-type elastic wavefilter 2, an attenuation pole is formed at a frequency (resonancefrequency of third parallel resonator 40) that is apart from thepassband of ladder-type elastic wave filter 2 in a frequency regionhigher than the passband. Thus, it is possible to secure attenuationcharacteristics in the frequency band that is apart from this passbandof ladder-type elastic wave filter 2 in a frequency region higher thanthe passband.

Each component of ladder-type elastic wave filter 2 of the secondexemplary embodiment is described below in detail. In ladder-typeelastic wave filter 2, series resonators 8, 9, 10, and 11, firstparallel resonators 12, 13, and 14, and third parallel resonator areformed on a piezoelectric substrate (not shown). Furthermore, inductor15 may be formed on a laminated ceramic substrate (not shown) on which apiezoelectric substrate is mounted, or may be formed on thepiezoelectric substrate directly or indirectly via a dielectric layer.

The piezoelectric substrate is, for example, lithium niobate(LiNbO₃)-based, or lithium tantalate (LiTaO₃)-based piezoelectricmonocrystal substrates. When a dielectric layer is formed on thepiezoelectric substrate, the dielectric layer is, for example, siliconoxide (SiO₂), silicon nitride (SiN), aluminum nitride (AlN), or alaminated body thereof.

Each of series resonators 8, 9, 10, and 11, first parallel resonators12, 13, and 14, and parallel resonator 40 is formed of a pair of combelectrodes and two reflectors sandwiching the comb electrodes. The combelectrodes constituting these resonators are formed of, for example,simple substance of metal including aluminum, copper, silver, gold,titanium, tungsten, molybdenum, platinum, or chromium, or alloysincluding the metal as a main component, or a laminated body thereof.Note here that the comb electrode may be an electrode that excites asurface acoustic wave such as SH (Shear Horizontal) wave, Reilly, or thelike, as primary wave, or may be an electrode that excites a bulk wavesuch as a Lamb wave.

Each of the numbers of electrode fingers (finger), the interdigitatingwidth of electrode fingers [μm] and capacitance [pF] of seriesresonators 8, 9, 10, and 11, first parallel resonators 12, 13, and 14,and third parallel resonator 40 are shown in Table 3.

TABLE 3 number of interdigitating electrode width of fingers electrodefingers capacitance (finger) (μm) (pF) series resonator 8 176 185 5.1first parallel resonator 12 164 154 4.2 series resonator 9 178 41 1.1first parallel resonator 13 98 91 2.5 series resonator 10 130 75 2.1first parallel resonator 14 116 117 3.2 series resonator 11 130 60 1.6third parallel resonator 40 36 39 1.1

The numbers of electrode fingers (finger), the interdigitating width ofelectrode fingers [μm] and capacitance [pF] of series resonators 108,109, 110, and 111, and parallel resonators 112, 113, and 114 ofconventional ladder-type elastic wave filter 102 of FIG. 13 is shown inTable 4.

TABLE 4 interdigitating number of width of electrode electrode fingerscapacitance fingers (finger) (μm) (pF) series resonator 108 176 185 5.1parallel resonator 112 164 154 4.2 series resonator 109 178 41 1.1parallel resonator 113 98 131 3.5 series resonator 110 130 75 2.1parallel resonator 114 116 117 3.2 series resonator 111 130 60 1.6

Characteristic comparison between ladder-type elastic wave filter 2 ofthe second exemplary embodiment and conventional ladder-type elasticwave filter 102 is shown in FIG. 8. A solid line in FIG. 8 shows acharacteristic of ladder-type elastic wave filter 2 of the firstexemplary embodiment and a broken line shows a characteristic ofconventional ladder-type elastic wave filter 102. In FIG. 8, theabscissa shows frequency [MHz], and the ordinate shows a gain [dB].

As shown in FIG. 8, it is understood that in ladder-type elastic wavefilter 2, steepness in an attenuation amount is improved in a frequencyband that is apart from the passband in the frequency region higher thanthe passband as compared with that of the conventional ladder-typeelastic wave filter 102.

Furthermore, in such a ladder-type elastic wave filter 2, FIGS. 9A to 9Kshow characteristic comparison between ladder-type elastic wave filter 2of the second exemplary embodiment and conventional ladder-type elasticwave filter 102 when capacitance C1 of first parallel resonator 13 andcapacitance C2 of third parallel resonator 40 are varied as shown in Ato K of Table 5 while the sum of capacitance C1 of first parallelresonator 13 and capacitance C2 of third parallel resonator 40 is madeto be a constant value, 3.6 [pF].

TABLE 5 capacitance C1 of capacitance C2 of C2/ first parallel resonator13 third parallel resonator 40 (C1 + C2) A 3.6 0 0 B 3.24 0.36 0.1 C2.88 0.72 0.2 D 2.52 1.08 0.3 E 2.16 1.44 0.4 F 1.8 1.8 0.5 G 1.44 2.160.6 H 1.08 2.52 0.7 I 0.72 2.88 0.8 J 0.36 3.24 0.9 K 0 3.6 1

FIG. 9A shows a case in which a ratio value of capacitance C2 of thirdparallel resonator 40 with respect to the total of capacitance C1 offirst parallel resonator 13 and capacitance C2 of third parallelresonator 40 is zero, that is, C2/(C1+C2)=0 is satisfied; FIG. 9B showsa case in which C2/(C1+C2)=0.1 is satisfied; FIG. 9C shows a case inwhich C2/(C1+C2)=0.2 is satisfied; FIG. 9D shows a case in whichC2/(C1+C2)=0.3 is satisfied; FIG. 9E shows a case in whichC2/(C1+C2)=0.4 is satisfied; FIG. 9F shows a case in whichC2/(C1+C2)=0.5 is satisfied; FIG. 9G shows a case in whichC2/(C1+C2)=0.6 is satisfied; FIG. 9H shows a case in whichC2/(C1+C2)=0.7 is satisfied; FIG. 9I shows a case in whichC2/(C1+C2)=0.8 is satisfied; FIG. 9J shows a case in whichC2/(C1+C2)=0.9 is satisfied; and FIG. 9K shows a case in whichC2/(C1+C2)=1 is satisfied, respectively.

As shown in FIGS. 9A to 9K, when the relation between capacitance C1 offirst parallel resonator 13 and capacitance C2 of third parallelresonator 40 satisfies 0.1≦C2/(C1+C2) 0.7, ladder-type elastic wavefilter 2 can secure an attenuation amount in the frequency band that isapart from the passband in a frequency region higher than the passbandand can suppress loss deterioration in this passband. WhenC2/(C1+C2)≦0.7 is satisfied, the loss deterioration in the passband ofladder-type elastic wave filter 2 can be suppressed because, in thiscase, it is possible to suppress the deterioration of electromechanicalcoupling coefficient K² calculated from the equivalent circuit thatsynthesizes first parallel resonator 13 and third parallel resonator 40.

In particular, as shown in FIGS. 9A to 9K, when the relation betweencapacitance C1 of first parallel resonator 13 and capacitance C2 ofthird parallel resonator 40 satisfies 0.1≦C2/(C1+C2)≦0.5, ladder-typeelastic wave filter 2 can secure an attenuation amount in the frequencyband that is apart from the passband in the frequency region higher thanthe passband and can further suppress loss deterioration in thispassband.

Furthermore, as shown in FIG. 7, it is desirable that third parallelresonator 40 is connected in parallel to first parallel resonator 13 byone of the parallel arms. First parallel resonator 13 has the smallestcapacitance among first parallel resonators 12, 13, and 14. As mentionedabove, whether or not it is possible to achieve both securing anattenuation amount in the frequency band that is apart from the passbandin the frequency region higher than the passband of ladder-type elasticwave filter 2 and suppressing loss deterioration in this passbanddepends upon the ratio of capacitance C1 of first parallel resonator 13with respect to capacitance C2 of third parallel resonator 40. That isto say, in order to achieve the both, third parallel resonator 40 isconnected in parallel to first parallel resonator 13 having the smallestcapacitance by one of the parallel arms, and thus the capacitance ofthird parallel resonator 40 can be made to be smaller. As a result, anoccupied area of third parallel resonator 40 in ladder-type elastic wavefilter 2 is reduced, and the size of ladder-type elastic wave filter 2can be reduced.

In addition, as shown in FIG. 7, it is desirable that third parallelresonator 40 is connected in parallel to first parallel resonator 13 byone of the parallel arms. First parallel resonator 13 is other thanfirst parallel resonator 12 that is nearest to input terminal 4 amongthe first parallel resonators. The electrode finger pitch of thirdparallel resonator 40 is smaller than electrode finger pitches of seriesresonators 8, 9, 10, and 11, and first parallel resonators 12, 13, and14, and electric power resistance of third parallel resonator 40 isrelatively low. Thus, when third parallel resonator 40 is not connectedto the parallel arm at an input terminal 4 side that requires thelargest electric power resistance but connected to a parallel arm otherthan the parallel arm, electric power resistance of ladder-type elasticwave filter 2 can be improved.

Furthermore, as shown in FIG. 10, it is desirable that third parallelresonator 40 has a configuration in which each of a plurality ofresonators 41 and 42 is cascade connected to each other. The electrodefinger pitch of third parallel resonator 40 is smaller than theelectrode finger pitches of series resonators 8, 9, 10, and 11, andfirst parallel resonators 12, 13, and 14, and electric power resistanceof third parallel resonator 40 is relatively low. Thus, when thirdparallel resonator 40 includes cascade-connected resonators 41 and 42,electric power resistance of third parallel resonator 40 is improved,and electric power resistance of ladder-type elastic wave filter 2 canbe enhanced. In particular, the cascade connection configuration ofresonators 41 and 42 is particularly preferable because electric powerresistance of third parallel resonator 40 can be enhanced when thecapacitance of third parallel resonator 40 is not more than that offirst parallel resonator 13 connected to the same parallel arm as thatof third parallel resonator 40.

Note here that the capacitance of each of resonators 41 and 42 is twiceas large as the capacitance of third parallel resonator 40 shown in FIG.7. As the means, for example, an interdigitating width of electrodefingers of each of resonators 41 and 42 may be twice as that of thirdparallel resonator 40 in FIG. 7, or the number of electrode fingers maybe twice as many as that of third parallel resonator 40 in FIG. 7. Asdescribed above, when third parallel resonator 40 includes a pluralityof cascade-connected resonators, by making capacitance of each resonatorequal to each other, the electric power resistance of third parallelresonator 40 can be further improved, and electric power resistance ofladder-type elastic wave filter 2 can be further improved. Furthermore,when the capacitance of third parallel resonator 40 is not more than thecapacitance of first parallel resonator 13, by making a total occupiedarea of resonators 41 and 42 constituting third parallel resonator 40larger than that of first parallel resonator 13, the electric powerresistance of third parallel resonator 40 can be improved.

Furthermore, third parallel resonator 40 shown in FIG. 10 is divided ina propagation direction of the elastic wave as shown in FIG. 11, and maybe a resonator including comb electrodes having electrode fingers inwhich each of the divided regions 43 and 44 is disposed in an oppositephase to each other, and reflectors 45 and 46 sandwiching the resonator.Each of the divided regions 43 and 44 forms each of resonators 43 and 44shown in FIG. 10. Note here that terminal 47 is connected to seriesresonators 9 and 10, and terminal 48 is connected to connection part 16.With this configuration, an area of electric power of third parallelresonator 40 can be reduced and the attenuation pole formed by thirdparallel resonator 40 is increased, thus the attenuation characteristicsin the frequency region higher than the passband of ladder-type elasticwave filter 2 are improved. Note here that third parallel resonator 40shown in FIGS. 10 and 11 is divided into two parts, but it may be threeparts or more so as to further improve the electric power resistance ofthird parallel resonator 40.

Furthermore, in antenna duplexer 1 such as a duplexer including a firstfilter and a second filter having a passband higher than a passband ofthe first filter, when ladder-type elastic wave filter 2 is used as thefirst filter having a relatively low passband, an attenuation amount inthe passband of the second filter can be secured by the first filter.That is to say, in the case of the above-mentioned ladder-type elasticwave filter 2, an attenuation amount in the passband of the receptionfilter 3 can be secured. However, ladder-type elastic wave filter 2 maybe used as a second filter having a relatively high passband.

Furthermore, ladder-type elastic wave filter 2 of the second exemplaryembodiment may be mounted on an electronic apparatus provided with asemiconductor integrated circuit element (not shown) connected to thefilter and an audio unit (not shown) such as a loudspeaker connected tothe semiconductor integrated circuit element (not shown). Thus,communication quality of the electronic apparatus can be improved.

Third Exemplary Embodiment

Hereinafter, an elastic wave element in accordance with a thirdexemplary embodiment of the present disclosure is described withreference to drawings. FIG. 12 is a circuit block diagram of antennaduplexer 1 on which a ladder-type elastic wave filter in accordance withthe third exemplary embodiment of the present disclosure is mounted.Unless otherwise described, a configuration of the elastic wave elementof the third exemplary embodiment is the same configurations as those ofthe elastic wave elements of the first and second exemplary embodiments.

In FIG. 12, antenna duplexer 1 on which the ladder-type elastic wavefilter is mounted in accordance with the third exemplary embodiment is,for example, an antenna duplexer for Band-8of the UMTS system, andincludes ladder-type elastic wave filter 2 as a transmission filter andreception filter 3 having a passband (925 MHz to 960 MHz) higher than apassband (880 MHz to 915 MHz) of ladder-type elastic wave filter 2.

Antenna duplexer 1 includes phase shifter 7 connected betweenladder-type elastic wave filter 2 and reception filter 3. Phase shifter7 allows the passband of each of the transmission and reception filtersto have a higher impedance in view of each other so as to improveisolation between the transmission and reception filters.

Reception filter 3 includes, for example, resonator 19 and longitudinalmode coupled filter 18, which are connected between antenna terminal 5and output terminal (balanced terminal) 6, and receives a receivedsignal from antenna terminal 5 and outputs it from output terminal 6.

Ladder-type elastic wave filter 2 as the transmission filter isconnected between input terminal 4 and antenna terminal 5 (an outputterminal of ladder-type elastic wave filter 2), receives a transmissionsignal from input terminal 4 and outputs it from antenna terminal 5.Ladder-type elastic wave filter 2 includes series resonators 8, 9, 10,and 11 each of which is connected to each of a plurality of series arms,and first parallel resonators 12, 13, and 14 each of which is connectedto each of a plurality of parallel arms, in which series resonators 8,9, 10, and 11 and first parallel resonators 12, 13, and 14 are connectedto each other in a ladder form. Resonance frequencies of first parallelresonators 12, 13, and 14 are lower than resonance frequencies orantiresonance frequencies of series resonators 8, 9, 10, and 11.

Furthermore, ground terminal 17 sides of first parallel resonators 12,13, and 14 are connected to each other at connection part 16,ladder-type elastic wave filter 2 includes inductor 15 connected betweenconnection part 16 and ground terminal 17.

In ladder-type elastic wave filter 2 thus constructed as thetransmission filter in antenna duplexer 1, the antiresonance frequenciesof series resonators 8, 9, 10, and 11 are set in the vicinity of thepassband of ladder-type elastic wave filter 2 in a frequency regionhigher than the passband of ladder-type elastic wave filter 2, and theresonance frequencies of first parallel resonators 12, 13, and 14 areset in the vicinity of the passband of ladder-type elastic wave filter 2in a frequency region lower than the passband of ladder-type elasticwave filter 2. Attenuation poles are thus formed in the both vicinitiesof the passband of ladder-type elastic wave filter 2 at the higher andlower frequency sides.

In addition, in antenna duplexer 1, ladder-type elastic wave filter 2includes second parallel resonator 20 connected in parallel to firstparallel resonator 12 by one of the parallel arms and having a resonancefrequency higher than the series resonance frequencies of resonators 8,9, 10, and 11 and lower than the antiresonance frequencies of seriesresonators 8, 9, 10, and 11. Second parallel resonator 20 operates as aband attenuation filter (notch filter) that attenuates an input signalaround the resonance frequency of second parallel resonator 20. Notehere that second parallel resonator 20 may be singly connected to aparallel arm between one of the series resonators and the groundterminal without being connected to any of the parallel arms to whichthe first parallel resonators are connected, respectively.

With the above-mentioned configuration, in ladder-type elastic wavefilter 2, an attenuation pole formed by the second parallel resonator isformed in a frequency region lower than the attenuation pole formed bythe series resonators in a frequency region higher than the passband ofladder-type elastic wave filter 2. This makes it possible to securesteepness of the passing characteristics in a frequency region higherthan the passband of ladder-type elastic wave filter 2.

Thus, when the resonance frequency of second parallel resonator 20 isset to be lower than the antiresonance frequency of series resonator 8having the lowest antiresonance frequency among series resonators 8, 9,10, and 11 in ladder-type elastic wave filter 2, the antiresonancefrequency of series resonator 8 can be shifted from the antiresonancefrequency of conventional series resonator 108 to a higher frequencyregion side, and heat generation of series resonator 8 can besuppressed. In this case, in second parallel resonator 20, sinceexcitation of primary elastic wave in the frequency region lower thanthe resonance frequency is suppressed, heat generation is suppressed. Asa result, electric power resistance of ladder-type elastic wave filter 2can be improved.

In addition, in antenna duplexer 1, ladder-type elastic wave filter 2includes third parallel resonator 40 connected in parallel to firstparallel resonator 13 by one of the parallel arms and having resonancefrequency higher than antiresonance frequencies of resonators 8, 9, 10,and 11. Third parallel resonator 40 operates as a band attenuationfilter (notch filter) that attenuates an input signal around theresonance frequency of third parallel resonator 40. Note here that thirdparallel resonator 40 may be singly connected to a parallel arm betweenone of the series resonators and the ground terminal without beingconnected to any of the parallel arms to which the first parallelresonators are connected, respectively.

With the above-mentioned configuration, in ladder-type elastic wavefilter 2, an attenuation pole is formed in a frequency (resonancefrequency of third parallel resonator 40) that is apart from thepassband of ladder-type elastic wave filter 2 in a frequency regionhigher than the passband. Thus, it is possible to secure attenuationcharacteristics in the frequency band that is apart from the passband ofladder-type elastic wave filter 2 in the frequency region higher thanthe passband.

That is to say, by connecting second parallel resonator 20 and thirdparallel resonator 40 in parallel to a signal line, it is possible tosecure attenuation characteristics in both in the vicinity of thepassband of ladder-type elastic wave filter 2 in the frequency regionhigher than the passband and in a frequency band that is apart from thepassband.

Furthermore, it is desirable that capacitance of second parallelresonator 20 is smaller than capacitance of third parallel resonator 40.The reason for this is described below. In a frequency region lower thanthe attenuation pole formed by second parallel resonator 20, secondparallel resonator 20 as a band attenuation filter shows capacitativeproperty. Thus, when capacitance of second parallel resonator 20 islarger than capacitance of third parallel resonator 40, steepness isdeteriorated in the frequency region lower than the attenuation poleformed by second parallel resonator 20 and in the frequency regionhigher than the passband of ladder-type elastic wave filter 2. Then,when the capacitance of second parallel resonator 20 is made to besmaller than capacitance of third parallel resonator 40, steepness canbe improved in the frequency region higher than the passband ofladder-type elastic wave filter 2.

Furthermore, when the capacitance of second parallel resonator 20 issmaller than the capacitance of third parallel resonator 40, and when atleast second parallel resonator 20 in second parallel resonator 20 andthird parallel resonator 40 includes a plurality of cascade-connectedresonators, it is desirable that the number of resonators constitutingsecond parallel resonator 20 is larger than the number of resonator(s)constituting third parallel resonator 40.

When the capacitance of second parallel resonator 20 is smaller than thecapacitance of third parallel resonator 40, the electric powerresistance of second parallel resonator 20 is lower as compared with theelectric power resistance of third parallel resonator 40. Thus, when thenumber of resonators constituting second parallel resonator 20 is madeto be larger than the number of resonator(s) constituting third parallelresonator 40, the electric power resistance of third parallel resonator40 can be secured, and the electric power resistance of ladder-typeelastic wave filter 2 can be improved.

Furthermore, in antenna duplexer 1 such as a duplexer including a firstfilter and a second filter having a passband higher than a passband ofthe first filter, when ladder-type elastic wave filter 2 is used as thefirst filter having a relatively low passband, an attenuation amount inthe passband of the second filter can be secured by the first filter.That is to say, in the case of the above-mentioned ladder-type elasticwave filter 2, an attenuation amount in the passband of the receptionfilter 3 can be secured. However, ladder-type elastic wave filter 2 maybe used as a second filter having a relatively high passband.

Furthermore, ladder-type elastic wave filter 2 of the third exemplaryembodiment may be mounted on an electronic apparatus provided with asemiconductor integrated circuit element (not shown) connected to thefilter and an audio unit (not shown) such as a loudspeaker connected tothe semiconductor integrated circuit element (not shown). Thus,communication quality of the electronic apparatus can be improved.

A ladder-type elastic wave filter in accordance with the presentdisclosure has a feature in which steepness of passing characteristic ina frequency region higher than the passband of a ladder-type elasticwave filter is secured, and it can is applicable for electronicapparatuses such as a portable telephone.

What is claimed is:
 1. A ladder-type elastic wave filter comprising: aninput terminal; an output terminal; a ground terminal; a seriesresonator connected between the input terminal and the output terminal;a first parallel resonator connected between the series resonator andthe ground terminal, and having a resonance frequency lower than anantiresonance frequency of the series resonator; and a second parallelresonator connected between the series resonator and the groundterminal, wherein a resonance frequency of the second parallel resonatoris higher than a resonance frequency of the series resonator and lowerthan the antiresonance frequency of the series resonator.
 2. Theladder-type elastic wave filter according to claim 1, wherein the secondparallel resonator is connected in parallel to the first parallelresonator.
 3. The ladder-type elastic wave filter according to claim 1,wherein the second parallel resonator has capacitance smaller thancapacitance of the first parallel resonator.
 4. The ladder-type elasticwave filter according to claim 3 further comprising parallel arms,wherein the first parallel resonator is connected to the seriesresonator via one of the parallel arms, and the second parallelresonator is connected to one of the parallel arms that is other than aparallel arm nearest to the input terminal.
 5. The ladder-type elasticwave filter according to claim 3, wherein the second parallel resonatorincludes cascade-connected resonators.
 6. The ladder-type elastic wavefilter according to claim 5, wherein each of the resonators included inthe second parallel resonator has equal capacitance to each other. 7.The ladder-type elastic wave filter according to claim 1 comprising: apiezoelectric substrate; comb electrodes formed on the piezoelectricsubstrate and including a first comb electrode constituting the firstparallel resonator and a second comb electrode constituting the secondparallel resonator; and a dielectric layer covering the comb electrodesand having a frequency temperature coefficient with an opposite sign toa frequency temperature coefficient of the piezoelectric substrate,wherein in the dielectric layer, a part on a second comb electrode isthicker than a part on a first comb electrode.
 8. The ladder-typeelastic wave filter according to claim 1 comprising: a piezoelectricsubstrate; comb electrodes formed on the piezoelectric substrate andincluding a first comb electrode constituting the first parallelresonator and a second comb electrode constituting the second parallelresonator; and a dielectric layer covering the second comb electrode andhaving a frequency temperature coefficient with an opposite sign to afrequency temperature coefficient of the piezoelectric substrate,wherein the dielectric layer is not provided on the first combelectrode.
 9. The ladder-type elastic wave filter according to claim 1further comprising: a third parallel resonator connected between theseries resonator and the ground terminal, and having a resonancefrequency higher than the antiresonance frequency of the seriesresonator.
 10. The ladder-type elastic wave filter according to claim 9,wherein the second parallel resonator has capacitance smaller thancapacitance of the third parallel resonator.
 11. The ladder-type elasticwave filter according to claim 10, wherein the second parallel resonatorincludes cascade-connected resonators, the third parallel resonatorincludes one resonator or a plurality of resonators, and, when the thirdparallel resonator includes the plurality of resonators, a number of theresonators included in the second parallel resonator is larger than anumber of the plurality of resonators included in the third parallelresonator.
 12. A ladder-type elastic wave filter comprising: an inputterminal; an output terminal; a ground terminal; a series resonatorconnected between the input terminal and the output terminal; a firstparallel resonator connected between the series resonator and the groundterminal, and having a resonance frequency lower than an antiresonancefrequency of the series resonator; and a third parallel resonatorconnected between the series resonator and the ground terminal, andhaving a resonance frequency higher than the antiresonance frequency ofthe series resonator.
 13. The ladder-type elastic wave filter accordingto claim 12, wherein relation between capacitance C1 of the firstparallel resonator and capacitance C2 of the third parallel resonatorsatisfies 0.1≦C2/(C1+C2)≦0.7.
 14. The ladder-type elastic wave filteraccording to claim 12, wherein relation between capacitance C1 of thefirst parallel resonator and capacitance C2 of the third parallelresonator satisfies 0.1≦C2/(C1+C2)≦0.5.
 15. The ladder-type elastic wavefilter according to claim 12, wherein the first parallel resonator isone of a first parallel resonators, the ladder-type elastic wave filtercomprises the first parallel resonators and parallel arms eachconnecting the series resonator and one of the first parallelresonators, and the third parallel resonator is connected in parallel toone of the first parallel resonators via one of the parallel arms, thefirst parallel resonator connected to the third parallel resonator has asmallest capacitance among the first parallel resonators.
 16. Theladder-type elastic wave filter according to claim 12 further comprisingparallel arms, wherein the first parallel resonator is connect to theseries resonator via one of the parallel arms, and the third parallelresonator is connected to one of the parallel arms that is other than aparallel arm nearest to the input terminal.
 17. The ladder-type elasticwave filter according to claim 12, wherein the third parallel resonatorincludes cascade-connected resonators.
 18. The ladder-type elastic wavefilter according to claim 17, wherein each of the resonators included inthe third parallel resonator has an equal capacitance to each other. 19.An antenna duplexer comprising: a first filter including the ladder-typeelastic wave filter defined in claim 1; and a second filter having apassband higher than a passband of the first filter.
 20. An antennaduplexer comprising: a first filter including the ladder-type elasticwave filter defined in claim 12; and a second filter having a passbandhigher than a passband of the first filter.